An oedometer test is a kind of

geotechnical investigation Geotechnical investigations are performed by geotechnical engineers or engineering geologists to obtain information on the physical properties of soil earthworks and foundations for proposed structures and for repair of distress to earthworks a ...

performed in geotechnical engineering that measures a

soil Soil, also commonly referred to as earth or dirt Dirt is an unclean matter, especially when in contact with a person's clothes, skin, or possessions. In such cases, they are said to become dirty. Common types of dirt include: * Debri ...

's consolidation properties. Oedometer tests are performed by applying different loads to a soil sample and measuring the

deformation Deformation can refer to: * Deformation (engineering), changes in an object's shape or form due to the application of a force or forces. ** Deformation (physics), such changes considered and analyzed as displacements of continuum bodies. * Defor ...

response. The results from these tests are used to predict how a soil in the field will deform in response to a change in

effective stress The effective stress can be defined as the stress, depending on the applied tension \boldsymbol_ and pore pressure p, which controls the strain or strength behaviour of soil and rock (or a generic porous body) for whatever pore pressure value or, ...

. Oedometer tests are designed to simulate the one-dimensional deformation and

drainage Drainage is the natural or artificial removal of a surface's water and sub-surface water from an area with excess of water. The internal drainage of most agricultural soils is good enough to prevent severe waterlogging (anaerobic condition ...

conditions that soils experience in the field. The soil sample in an oedometer test is typically a circular disc of diameter-to-height ratio of about 3:1. The sample is held in a rigid confining ring, which prevents lateral

displacement Displacement may refer to: Physical sciences Mathematics and Physics * Displacement (geometry), is the difference between the final and initial position of a point trajectory (for instance, the center of mass of a moving object). The actual path ...

of the soil sample, but allows the sample to swell or compress vertically in response to changes in applied load. Known vertical stresses are applied to the top and bottom faces of the sample, typically using free weights and a

lever arm In physics and mechanics, torque is the rotational equivalent of linear force. It is also referred to as the moment of force (also abbreviated to moment). It represents the capability of a force to produce change in the rotational motion of ...

. The applied vertical stress is varied and the change of the thickness of the sample is measured. For samples that are saturated with water,

porous Porosity or void fraction is a measure of the void (i.e. "empty") spaces in a material, and is a fraction of the volume of voids over the total volume, between 0 and 1, or as a percentage between 0% and 100%. Strictly speaking, some tests measure ...

stones are placed on the top and bottom of the sample to allow drainage in the vertical direction, and the entire sample is submerged in water to prevent drying. Saturated soil samples exhibit the phenomenon of consolidation, whereby the soil's volume changes gradually to give a delayed response to the change in applied confining stresses. This typically takes minutes or hours to complete in an oedometer and the change of sample thickness with time is recorded, providing measurements of the coefficient of consolidation and the permeability of the soil.

Etymology

The word "oedometer" ( , sometimes ) is derived from Ancient Greek οἰδέω (''oidéō'', "to swell"), which also gave rise to the English word

oedema Edema, also spelled oedema, and also known as fluid retention, dropsy, hydropsy and swelling, is the build-up of fluid in the body's tissue. Most commonly, the legs or arms are affected. Symptoms may include skin which feels tight, the area ma ...

. This should not be confused with the similar-looking but unrelated word " odometer", derived from Ancient Greek ὁδός (''hodos'', "path") which refers to a device to measure the distance travelled by a vehicle.

History

Consolidation experiments were first carried out in 1910 by Frontard. A thin sample (2in thick by 14in in diameter) was cut and placed in a metal container with a perforated base. This sample was then loaded through a piston incrementally, allowing equilibrium to be reached after each increment. To prevent drying of the clay, the test was done in a room with high humidity.Bjerrum, Laurits; Casagrande, Arthur; Peck, Ralph; Skempton, Alec. (1960). ''From Theory to Practice in Soil Mechanics''. (p44) John Wiley & Sons, Inc.

Karl von Terzaghi Karl von Terzaghi (October 2, 1883 – October 25, 1963) was an Austrian mechanical engineer, geotechnical engineer, and geologist known as the "father of soil mechanics and geotechnical engineering". Early life In 1883, he was born the first ch ...

started his consolidation research in 1919 at Robert College in Istanbul. Through these experiments, Terzaghi started to develop his theory of consolidation which was eventually published in 1923. The

Massachusetts Institute of Technology The Massachusetts Institute of Technology (MIT) is a private land-grant research university in Cambridge, Massachusetts. Established in 1861, MIT has played a key role in the development of modern technology and science, and is one of the ...

played a key role in early consolidation research. Both Terzaghi and

Arthur Casagrande Arthur Casagrande (August 28, 1902 – September 6, 1981) was an American civil engineer born in Austria-Hungary who made important contributions to the fields of engineering geology and geotechnical engineering during its infancy. Renowned for h ...

spent time at M.I.T. - Terzaghi from 1925 to 1929 and Casagrande from 1926 to 1932. During that time, the testing methods and apparatuses for consolidation testing were improved.Bjerrum, Laurits; Casagrande, Arthur; Peck, Ralph; Skempton, Alec. (1960). ''From Theory to Practice in Soil Mechanics''. (p6-7) John Wiley & Sons, Inc. Casagrande's contributions to the technique of oedometer testing includes the "Casagrande method" to estimate the pre-consolidation pressure of a natural soil sample. Research was continued at MIT in the 1940s by Donald Taylor.Taylor, Donald W. (1942). ''Research on Consolidation of Clays''. Massachusetts Institute of Technology Both the

British Standards Institute The British Standards Institution (BSI) is the national standards body of the United Kingdom. BSI produces technical standards on a wide range of products and services and also supplies certification and standards-related services to business ...

and the ASTM have standardised methods of oedometer testing. ASTM D2435 / D2435M - 11 covers oedometer testing by incremental loading. ASTM D3877, ASTM D4546 and AASHTO T216 also provide related procedures for conducting other similar tests for determination of the consolidation characteristics of soils. BS 1377-5:1990 is the relevant British Standard for oedometer testing; the wider BS 1377 series also provides background information and best-practice advice on sample preparation for various geotechnical investigations. There are also two ISO standards on oedometer testing: ISO 17892-5:2017 on incremental loading oedometer tests; and BS EN ISO 17892-11:2019 covers various methods of soil permeability testing, including oedometer tests on saturated samples.

Equipment

An oedometer is fundamentally made out of three components: a "consolidation cell" to hold the soil sample, a mechanism to apply a known pressure over the sample, and an instrument to measure the changes in the sample's thickness. The equipment required to perform an oedometer test is sometimes called an "oedometer test set". A typical inventory of an oedometer laboratory includes: *1 x Bench * 3 x Oedometers * 3 x Cells, either 50mm or 63.5mm, or 75mm * 3 x Dial gauges, either analogue, or digital * 1 x Weight set The consolidation cell is the part of the oedometer that holds the soil sample during a test. At the centre of the consolidation cell is a sample ring where the soil sample is held. The sample ring is typically shaped like a

cookie cutter A cookie cutter in North American English, also known as a biscuit cutter outside North America, is a tool to cut out cookie/biscuit dough in a particular shape. They are often used for seasonal occasions when well-known decorative shapes are ...

, with a sharp edge on one side, so the ring can be used to cut out a sample slice of soil from a larger block of natural soil. Two slices of porous stone, which fit snugly into the sample ring, provide water drainage to the soil sample while confining it mechanically. These components all fit in a larger cylinder, which has grooves to ensure alignment of the components, and provides water supply and drainage to external plumbing. A rigid loading cap sits on top of the soil sample to apply compressive loads to the soil. The loading mechanism of the oedometer applies a known compressive load, and therefore a known compressive stress since the diameter is fixed, to the soil sample. Most oedometers achieve this with a lever arm and a set of free weights: the free weights provide a known gravitational load, and the lever arm multiplies and transmits the load to the soil sample.

Testing procedures

There are many oedometer tests that are used to measure consolidation properties. The most common type is the incremental loading (IL) test.Terzaghi, Karl; Peck, Ralph; Mesri, Gholamreza (1996). ''Soil Mechanics in Engineering Practice'' (3rd Edition). (Article 16.9) Wiley-Interscience

Sample preparation

Tests are carried out on specimens prepared from undisturbed samples. A stiff confining ring with a sharp edge is used to cut a sample of soil directly from a larger block of soil. Excess soil is carefully carved away, leaving a sample with a diameter-to-height ratio of 3 or more. Porous stones are placed on the top and bottom of the sample to provide drainage. A rigid loading cap is then placed on top of the upper porous stone. For saturated soil samples, it is important to submerge the entire sample ring in water to prevent the sample from drying out.

Incremental loading

This assembly is then placed into a loading frame. Weights are placed on the frame, imposing a load on the soil. Compression of the sample is measured over time by a dial indicator. By observing the deflection value over time data, it can be determined when the sample has reached the end of primary consolidation. Another load is then immediately placed on the soil and this process is repeated. After a significant total load has been applied, the load on the sample is decreased incrementally. Using a load increment ratio of 1/2 provides a sufficient number of data points to describe the relationship between void ratio and effective stress for a soil.

Results

Oedometer tests provide engineers with very useful data about the soil being tested. Coefficient of volume compressibility

m_v=\frac \frac

derivied from Oedometer test

\Delta H=m_v  H_0

Applied to layer in field (see pictures)

Consolidation Properties

* Preconsolidation pressure σ'_''p''Terzaghi, Karl; Peck, Ralph; Mesri, Gholamreza (1996). ''Soil mechanics in Engineering Practice'' (3rd Edition). (Article 16.4) Wiley-Interscience ** The effective stress that marks the boundary between stiff and soft deformation response of a soil to loading ** Usually indicative of high loadings in the past from glaciers or eroded layers * Recompression Index C_R = Δ''e''/Δlogσ'_''v''Terzaghi, Karl; Peck, Ralph; Mesri, Gholamreza (1996). ''Soil mechanics in Engineering Practice'' (3rd Edition). (Article 16.6) Wiley-Interscience ** How the soil will change volume (settle) under loads less than the preconsolidation pressure ** Can be used to approximate swelling due to unloading * Compression Index C_C = Δ''e''/Δlogσ'_''v'' ** How the soil will change volume (settle) under loads greater than the preconsolidation pressure * Duration of Primary Consolidation ''t''_pTerzaghi, Karl; Peck, Ralph; Mesri, Gholamreza (1996). ''Soil mechanics in Engineering Practice'' (3rd Edition). (Article 16.7) Wiley-Interscience * Secondary Compression Index C_α = Δ''e''/Δlog''t'' ** How the soil will change volume (settle) under a constant loading

References

{{Geotechnical engineering Tests in geotechnical laboratories